GIS英文期刊简介

《Journal of Urban Planning and Development》是美国土木工程学会（American Society of Civil Engineers，ASCE）出版的英语学术期刊，专注于工程：土木领域。

该期刊创刊于1983年，为季刊。

根据2015年JCR（Journal Citation Reports）影响因子排名，该期刊在城市研究领域排名第二。

《Journal of Urban Planning and Development》的主要内容包括城市规划、设计、建设、维护和城市交通等方面的当代活动报告。

期刊接收经过同行评审的研究论文、案例分析、技术报告和综述文章。

至于期刊的分区，根据我国教育部公布的《学位授予和人才培养学科目录》，城市规划与设计、土木工程等学科属于工学门类。

因此，可以将《Journal of Urban Planning and Development》视为一个工学领域的期刊。

此外，根据期刊的自引率（23.4%）和审稿周期（暂无数据），该期刊在城市规划与发展领域具有较高的影响力。

期刊每年发表约94篇文章，投稿命中率暂无具体数据。

我国地理信息系统技术的刊物及特点地理信息系统（Geographic Information System，简称GIS）是一种将地理空间数据与属性数据相结合，进行存储、管理、分析、查询和可视化的技术系统。

在我国，地理信息系统技术得到了广泛的应用和发展，相关的刊物也相应涌现出来。

以下将对我国地理信息系统技术的刊物及其特点进行解释。

1.《地理信息世界》《地理信息世界》是中国地理信息系统协会主办的一本综合性刊物，旨在推动我国地理信息技术的发展和应用。

该刊物聚焦于地理信息系统在国家建设、经济发展、环境保护等方面的应用与创新，涵盖了地理信息系统理论研究、技术应用、案例分析等内容。

特点是严谨性、专业性强，文章涉及的领域广泛，对读者具有较高的参考价值。

2.《GIS科学》《GIS科学》是中国测绘学会地理信息系统专业委员会主办的学术期刊，旨在推动地理信息科学的研究与应用。

该刊物关注地理信息科学理论与方法的创新，以及地理信息系统在资源环境、城市规划、农业、林业等领域的应用研究。

特点是理论性强，注重学术研究和技术创新，对提高地理信息科学研究水平具有重要意义。

3.《地理空间信息》《地理空间信息》是中国科学院地理科学与资源研究所主办的地理信息科学学术期刊，旨在推动地理空间信息科学的发展与应用。

该刊物涵盖了地理信息系统、遥感、地理空间数据挖掘等领域的研究与应用，特点是学术性强，对地理空间信息科学的研究与发展起到了积极的推动作用。

4.《测绘通报》《测绘通报》是中国测绘学会主办的专业学术期刊，涵盖了地理信息系统、遥感、大地测量、地图制图等领域的研究成果与应用案例。

该刊物特点是实用性强，聚焦于测绘技术与应用，对地理信息系统技术的研究与应用具有重要意义。

以上是我国地理信息系统技术的一些主要刊物及其特点。

这些刊物在推动地理信息系统技术的发展和应用方面发挥了积极的作用，为相关领域的学术研究和实际应用提供了重要的参考和支持。

同时，这些刊物也反映了我国地理信息系统技术的发展水平和应用成果，为学术界和行业提供了交流和分享的平台。

地理学sci期刊介绍地理学是一门研究地球表面及其上自然环境和人文环境相互关系的学科。

与其他学科一样，地理学研究也需要通过学术期刊来传播和交流最新的研究成果。

SCI（Science Citation Index）期刊是国际上具有重要影响力的学术期刊索引体系，被广泛接受和使用。

本文将介绍几种地理学领域中著名的SCI期刊。

1. Journal of Geophysical Research: Atmospheres《地球物理研究期刊：大气层》是一本SCI经典学术期刊，涵盖了大气物理、气象学和气候学等多个研究方向。

该期刊创刊于1896年，由美国地球物理学会（American Geophysical Union）主办，是地理学领域最具影响力的期刊之一。

该期刊的论文主要关注大气环境和气候变化等问题，为地理学研究者提供了广泛的交流平台。

2. Geographical Research《地理研究》是一本由澳大利亚地理学会（Institute of Australian Geographers）主办的SCI期刊，创刊于1963年。

该期刊旨在促进地理学理论与实践的交流，涵盖了人文地理学、自然地理学和地理信息系统等多个研究领域。

《地理研究》的论文内容丰富多样，既包括地理学基础理论研究，也包括对具体地区和问题的实证分析，对地理学研究者来说具有很高的参考价值。

3. Annals of the Association of American Geographers《美国地理学协会年鉴》是美国地理学协会（Association of American Geographers）的官方学术期刊，旨在提高地理学研究的质量和传播的效果。

该期刊创刊于1911年，是地理学领域历史最悠久的期刊之一。

《美国地理学协会年鉴》的论文内容广泛，涵盖了人文地理学、社会地理学、经济地理学、城市地理学等诸多领域。

该期刊注重理论研究和方法创新，为地理学界提供了独特的学术交流平台。

1GIS（地理信息系统）概述地理信息系统（GIS，Geographic Information System）是在计算机硬、软件系统支持下，对现实世界（资源与环境）的研究和变迁的各类空间数据，及描述这些空间数据特性的属性进行采集、储存、管理、运算、分析、显示和描述的技术系统，它作为集计算机科学、地理学、测绘遥感学、环境科学、城市科学、空间科学、信息科学和管理科学为一体的新兴边缘学科而迅速地兴起和发展起来。

1.1GIS的历史“地理信息系统（GIS）”概念的提出，要追溯到20世纪50年代。

由于电子计算机科学的兴起和它在测量学与地图制图学中的应用，使人们开始有可能用电子计算机来收集、存储和处理各种与空间和地理分布有关的图形和属性数据，并希望通过计算机对数据的分析来直接为管理和决策服务。

1956年，奥地利测绘部门首先利用电子计算机建立了地籍数据库，随后各国的土地测绘和管理部门都逐步发展土地信息系统（LIS）用于地籍管理。

20世纪60年代为GIS开拓期。

1963年，加拿大测量学家R .F.Tomlinson首先提出地理信息系统这一术语，并建立了世界上第一个GIS——加拿大地理信息系统（CGIS），用于自然资源的管理与规划。

本年代内，IBM公司和COLORADO公共服务公司开始致力于用计算机工具管理公用事业的设施，也就是电力线、煤气管道、阀门、仪表、土地等。

紧接着的一个十年，其他人继续挑战“计算机化的设施管理”（FM），包括计算机制图系统，并且诞生了自动制图（AM）。

FM、AM、计算机辅助设计（CAD）及数据库管理（Database Management）等学科的发展为GIS技术的发展创造了条件。

许多大学研制了GIS软件包，如哈佛计算机图形与空间分析实验室开发了SYMAP系列软件。

早期的GIS发展的另一个显著特点是许多与GIS有关的组织与机构纷纷成立，对GIS知识传播与技术发展起到重要的指导作用。

进入20世纪70年代，受计算机软硬件技术飞速发展的促进，GIS技术朝实用化方向发展。

关于城市研究：1. Uban Studies该期创刊于１９６４年格拉斯哥大学（ＵｎｉｖｅｒｓｉｔｙｏｆＧｌａｓｇｏｗ），其主旨在于从多角度、多方位地报道地理学、经济学、社会学和政治学中与城市、区域、规划和公共管理密切相关的研究的进展情况。

2.Journal of Urban Affairs该期刊季刊是由美国“城市事务联合会”(Urban Affairs Association简称UAA,），于1969年由一批大学教授创立于波士顿。

其编委主要为城市研究方面的著名人士，其论文主要围绕城市地区环境、大都市区及社区问题的理论、概念等问题，同时关注理论和规划建设实践工作，质量上乘，颇有深度，是公共政策和城市研究领域的主要期刊。

ndscape and Urban Planning该期刊由艾尔斯威尔(Elsevier)出版集团出版，主要关注土地利用的概念、科学和设计理论等。

该期刊的文章主要从生态角度、采用多元化的方法进行城市分析、规划和设计的理论与实证研究。

4.CitiesCities是以城市政策和规划为主要研究对象的期刊双月刊，这一创办于1983年的期刊颇为年轻，但发展迅速。

该期刊以介绍城市发展及其管理和规划为主，覆盖的城市范围颇广，其专题内容甚至包括非洲、中东等地区的不常出现在其他城市研究类学术期刊上的城市。

其文章主题涉及住房、无家可归问题、健康、城市管理、公共或私有产业、第三世界发展与规划、城市更新、城市保护和设计、技术创新和城市规划、城市交通等。

5. International Journal of Urban and Regional Research该期刊(季刊)创刊于1977年，简称IJURR是城市研究领域坡为重要的国际期刊。

该刊由英国黑井(Blackwell)出版公司负责出版.该期刊主要刊登有关城市与区域研究方面的观点、思想的文章与评论等，侧重于从社会科学的角度来研究城市。

关于规划与发展：1. Journal of the American Planning Association该期刊(季刊)是规划类和城市研究类期刊中的主要期刊，是规划类中影响因子排名最前的SSCI期刊，简称JAPA.作为美国规划师联合会的主要出版物，JAPA起源于1909年的美国国家城市规划会议(NationalConference on City Planning,简称NCCP). JAPA的作者主要来自规划界和学术界，文章侧重对政策、技术和实际规划项日的报道。

Geographic Information SystemsGeographic Information Systems integrate computer hardware, software, and trained personnel to link resource data that are geographically referenced (NASA’s define). Computer allows one to access or display data spatially, locate points, lines or areas geographically, associate data with them, and allows retrievals and calculations to be made based upon geographic locations. They store where’s and what’s, coordinates and associated attributes. A GIS staff (trained personnel) is organised to take care of maintaining the system, guiding and controlling input of data, and supporting users during the project period.The U.S. Geological Survey offers a frequently cited definition of GIS: “A computer system capable of capturing, storing, analyzing, and displaying geographically referenced information; that is, data identified according to location. Practitioners also define a GIS as including the procedures, operating personnel, and spatial data that go into the system.”GIS allows any data with a geographic component (city, ZIP Code, country, etc.) to be displayed on a map.Much of the power of GIS lies in its ability to layer information and data. Data that mean little in table format can make a strong visual impact as a map. For instance, a table of rainfall amounts in major Virginia cities may not be as effective as a map of Virginia displaying the cities and their rainfall amounts. GIS takes this idea a step further: it enables sets of data from a database to be displayed together on demand, even in unusual combinations, and therefore can reveal patterns that otherwise would be difficult to see.Historical BackgroundThe predecessors to GIS are unique uses of maps. Historically, maps were used solely for displaying geographic boundaries and features. One famous exception is a map of London created by Dr. John Snow in 1854. He suspected that an outbreak of cholera was tied to the water system. To investigate, he plotted the London water system and locations where people died from cholera on a map. This map revealed a possible relationship between the water system and the disease —an idea contrary to mainstream thinking at the time. The outbreak was eventually traced to acontaminated pump shown on Snow’s map.Another well-known example of a unique use of a map is Charles Joseph Minard’s “Losses of French Army in Napoleon’s Russian Campaign.”This 1869 map represents Napoleon’s army as a bar and plots its locations as it enters and exits Russia over time. The start of the campaign is represented as a wide bar along the Polish-Russian border. The bar narrows as it proceeds into Russia, and by the time it returns to Poland the bar has thinned to the width of a pen stroke—a dramatic representation of the army’s losses.The first technological forerunner of modern GIS was the Canada Geographic Information System, created by the Canadian government to classify uses of land. This system, developed in the 1960s, brought about many technological advances that eventually led to today’s GIS technologies. The most widely used technology today is ESRI’s ArcGIS system. Similar systems are available, such as those by MapInfo.FeaturesGIS gives new visual access to data by layering them with mapping/spatial information. Layering data allows you to adjust their display and conduct analysis ranging from basic to complex. Some typical uses for GIS include the following: ﹒Mapping: creating maps for basic analysis and communication﹒Planning: using GIS as an analytical tool to assist in planning decisions, such as selecting the site for a new store location﹒Research: using GIS as an analytical tool to explore research questions, find new relationships between data, and find new patterns in data﹒Routing: using GIS to delineate efficient route options (for example, shipping companies plotting delivery routes).Recently developed Web-based GIS (the integration of Web technology into GIS) applications make the technology even more powerful. These applications offer several benefits:﹒Inexpensive distribution of electronic maps and mapping data, whether over the Internet or a corporate intranet﹒Interactivity, which permits users to adjust the appearance of maps to meet their needs﹒Electronic map formats, which allow users to use the electronic maps generated in other documents or formatsTypes of GISGeographical variation, in the real worlds is infinitively complex. The closer you look the more detail you see almost without limit. It would take an infinitively large database to capture the real world precisely data must somehow be reduced to a finite and manageable quantity by a process of generalization or abstraction. Geographical variation must be represented in terms of discrete elements or objects. The rules used to convert real geographical variation into discrete objects is the data model. Data model is set of guidelines for the representation of the logical organization of the data in a database.Current GISs differ according the way in which they organize reality through the data model. Each model tends to fit certain types of data and applications better than others. The software available, the training of the key individuals and historical precedent, also influences the data model chosen for a particular project or application. There are two major choices of data model: raster and vector.Raster model divides the entire study area into a regular grid of cells in specific sequence. The conventional sequence is row by row from the top left corner. Each cell contains a single value. It is space-filling since every location in the study area corresponds to a cell in the raster. One set of cells and associated values is called as layer or coverage. There maybe many layers in a database, e.g. soil type, elevation, land use, land cover.Vector model uses discrete line segments or points to identify locations. Discrete objects (boundaries, streams, cities) are formed by connecting line segments. Vector objects do not necessarily fill space, not all locations in space need to be referenced in the area.A raster model tells what occurs everywhere at each place in the area. A vector model tells where everything occurs and gives a location for every object.Conceptually the raster models are the simplest of the available data models.Raster GISConsider a raster by coding each cell with a value that represents the rock type, which appears in the majority of that cell areas, when finished every cell, will have a coded value. There are several methods for creating raster databases. Direct entry of each layer cell by cell is the simplest. Much raster data is already in digital form, as images. Remote sensing generates images in the digital form. The type of values contained in a raster depends on both the reality being coded and the GIS. Each pixel or cell is assumed to have only one value.The data for an area can be visualised as a set of maps of layers. Only one item of information is available for each location within a single layer. Multiple items of information require multiple layers. Typical raster databases contain up a hundred layers. Each layer typically contains hundreds or thousands of cells.Important characteristics of a layer are its resolution, orientation and zone(s). In general resolution can be defined as the minimum linear dimension of the smallest unit geographic space for which data are recorded. The smallest units are known as cells, pixels. High resolution refers to rasters with small cell dimensions. Orientation is the angle between through north and the direction defined by the columns of the raster. Each zone of a map layer is a set of contiguous locations that exhibit the same value. These might be: ownership parcels, political units such as countries or nations, lakes or islands or individual patches of the same soil or vegetation type.Value is the item of information stored in a layer for each pixel or cell. Cells in the same zone have the same value. Location is defined by an ordered pair of coordinates that identify the location of each unit of geographic space in the raster.The vector or object GISVector data model based on vectors. Fundamental primitive is a point. Connecting points with straight lines create objects. Areas are defined by sets of lines. The term polygon is synonymous with area in vector databases because of the use of straight-line connection between points. Very large vector databases have been built for different purposes.Area objects in one class or layer cannot overlap and must exhaust the space of a layer. Every piece of boundary line is a common boundary between two areas. The strech of common boundary between two junctions (nodes) has various names such as edge, chain or arc. Arc is used by several systems and has attributes, which identify the polygons on either side. Arcs are fundamental in vector GIS. There are two ways of storing areas. In polygon storage every polygon is stored as a sequence of coordinates. Although most boundaries are shared between two adjacent areas, all are in out and coded twice, once for each adjacent polygon. This method is used by many automated mapping packages. The second method is arc storage. In this method every arcs is stored as a sequence of coordinates. Areas are built by linking arcs. Only one version of each internal shared boundary is input and stored. Used in most current vector-based GISs.Sampling the worldThe world is infinitely complex. The contents of a spatial database represent a particular view of the world. The used sees the real world through the medium of the database. The measurements and samples contained in the database must present as complete and accurate a view of the world as possible. The contents of the database must be relevant in terms of themes and characteristics captured, the time period covered and the study area.A database consists of digital representation of discrete objects. The features shown on a map, e.g. lakes, benchmarks, contours can be through of as discrete objects. Thus the contents of a map can be captured in a database by turning map features into database objects. Many of the features shown on a map are fictitious and do not exist in the real world. Contours do not really exist, but houses and lakes are real objects. The contents of a spatial database include: digital versions of real objects, e.g. houses, digital versions of artificial map features, e.g. contours and artificial objects created for the purpose of the database, e.g. pixels.Some characte ristics exist everywhere and vary continuously over the earth’s surface e.g. elevation, atmospheric temperature and pressure, natural vegetation or soil type. This kind of variation can be represented in a several ways: by takingmeasurements at sampling points, e.g. weather station; by taking transects; by dividing the area into patches or zones, and assuming the variable is constant, within each zone, e.g. soil mapping; by drawing contours, e.g. topographic mapping.Each of these methods creates discrete objects. The objects in each case are points, lines or areas.Since the 1960s, GIS has quietly transformed decision-making in universities, government, and industry by bringing digital spatial data sets and geographic analysis to desktop computers. Geographic Information Sciences include Geographic Information Systems as well as the disciplines of geography (examining the patterns of the Earth’s people and physical environment), cartography (mapmaking), geodesy (the science of measuring and surveying the Earth), and remote sensing (studying the Earth from space). GIS also provide a technology and method to analyze spatial data, or information about the Earth. The earth’s climate, natural hazards, population, geology, vegetation, soils, land use, and other characteristics can be analyzed in a GIS using computerized maps, aerial photographs, satellite images, databases, and graphs. By analyzing phenomena about the Earth’s hydrosphere, lithosphere, atmosphere, and biosphere, a GIS helps people understand patterns, linkages, and trends about our planet.《地理信息系统》参考译文根据NASA的定义，地理信息系统（GIS）是指由专业人员利用计算机硬件和软件将各种地理资源数据连接的系统。

综合类：1. PE&RS美国摄影测量与遥感协会的会刊，摄影测量工程与遥感(Photogrametry Engineering and remote sensing)杂志,网址，网上可看论文摘要，全文可去系图书室复印，该杂志南大很全，过去50年的都有,同时你可以发现测绘学报、遥感学报、武测学报甚至国外的文章中参考文献许多来自该刊，在2000年SCI地学类杂志排名中该刊名列第三，相当地不容易，南大校友美国berkeley加州大学副教授宫鹏就曾三次获得该刊的年度最佳论文奖，由此奠定其在国际遥感学界的地位。

2. IEEE Transactions on Geoscience and Remote Sensing国际电子与电器工程师协会地球科学与遥感协会IEEE Geoscience and Remote Sensing Society (GRSS) ，系图书室有原文，可复印，东南大学有近20年的电子版全文数据库。

不过这种研究大都从传感器和遥感机理研究，不适合我校的方向，浏览还是可以的，文中多是IEEE会员的文章很多，象美国NASA\JPL 在上面著文很多，中国学者很少能在上面发表文章。

3. ITC Journal荷兰ITC 校刊，多GIS和遥感专题应用文章,跟地理学结合很紧密，1999年改名JAG Journal, 南大有98年以前的杂志，前几天我又看到2001年的杂志。

）ITC网址Http://www.itc.nl文章全文用英文，附有德文和法文摘要。

4. ISPRS Journal of Photogrammetry & Remote Sensing国际摄影测量与遥感协会ISPRS的会刊,有介绍，Elsevier数据库上有全文。

该杂志现在多分主题出版，介绍当今摄影测量与遥感最新动态，如建立DEM，TIN，激光测高，干涉测量等技术，还是有不少好文章的）不过南大图书室没有订阅该刊，大家去看电子版吧。